Browse > Article
http://dx.doi.org/10.5322/JES.2007.16.3.347

Estimation of Compressive Strength of Concrete Using Blast Furnace Slag Subjected to High Temperature Environment  

Han, Min-Cheol (Division of Architectural Engineering, Cheongju University)
Shin, Byung-Cheol (Department of Landscape Architecture, Joongbu University)
Publication Information
Journal of Environmental Science International / v.16, no.3, 2007 , pp. 347-355 More about this Journal
Abstract
In this paper, estimation of the compressive strength of the concrete incorporating blast furnace slag subjected to high temperature was discussed. Ordinary Portland cement and blast furnace slag cement (BSC;30% of blast furnace slag) were used, respectively. Water to binder ratio ranging from 30% to 60% and curing temperature ranging from $20^{\circ}C{\sim}65^{\circ}C$ were also chosen for the experimental parameters, respectively. At the high temperature, BSC had higher strength development at early age than OPC concrete and it kept its high strength development at later age due to accelerated latent hydration reaction subjected to high temperature. For the strength estimation, the Logistic model based on maturity equation and the Carino model based on equivalent age were applied to verify the availability of estimation model. It was found that fair agreements between calculated values and measured values were obtained evaluating compressive strength with logistic curve. The application of logistic model at high temperature had remarkable deviations in the same maturity. Whereas, the application of Carino model showed good agreements between calculated values and measured ones regardless of type of cement and W/B. However, some correction factors should be considered to enhance the accuracy of strength estimation of concrete.
Keywords
High temperature; Maturity; Strength development; Blast furnace slag; Logistic model; Equivalent age;
Citations & Related Records
연도 인용수 순위
  • Reference
1 鎌田英治, 洪悦郎, 林直樹, 1990, 寒中コンク リ-トを對象としたコンクリ-ト强度増進曲線の檢討, セメント技術年報, 1-25
2 Carino N. J., 1984, Maturity method; theory and application., J. Cement Concrete and Aggregate, ASTM, 1-12
3 Kada-Benameur E., Wirquin B. D., 2003, Determination of apparent activation energy of concrete by isothermal calorimetry, Cement and Concrete Research, 30, 301-305   DOI   ScienceOn
4 Kjellsen K.O., 1999, Heat curing and post-heat curing regimes of high performance concrete ; Influence of microstructure and C-S-H composition, Cem. Concr. Res., 26(2), 295-307   DOI   ScienceOn
5 Escalente-Garcia J. I., Sharp J. H., 2004, The micro-structure and mechanical properties of blended cements hydrated at various temperatures, Cem. Concr. Res., 31, 695-702
6 Bernhardt, 1956, Hardening of concrete at Different Temperatures, RILEM Symposium on Winter Concreting, Institute for Building Research
7 Carino N. J., Tank R. C., 1992, Maturity functions for concretes made with various cements and admixtures, ACI Materials Journal, 188-196
8 한천구, 한민철, 1999, 적산온도방식의 콘크리트 강도증진해석에 의한 기온보정강도의 검토, 대한건축학회 논문집 구조계, 15(11),71-78
9 寺田米男, 1986, 各種セメントを用いたモルタ ルコンクリトの强度推定方法について, セメン ト技術年報, 35. 1-35
10 笠井芳夫, コンクリ-トの初期强度初期養生に關する硏究, 博士學位論文, 建築工學科, 東京大學, 日本
11 友浬史紀, 1998, コンクリトの促進養生とその 辿築生庄工業化への利用第皿編コンクリートの 岨度設現附する速度論的研究,コンクリート士 11-23
12 한천구, 한민철, 2002, 기온과 콘크리트, 1판, 기문당,1-100pp
13 Chengju G., 1989, Maturity of concrete, method for predicting early-stage strength, ACI Materials Journal, 86(4), 341-353
14 Naik T. R., 1992, Maturity of concrete ; Its application and limitations, CANMET, 329 -359
15 Plowman J. M., 1956, Maturity and strength of concrete. Magazine of Concrete Research (London), 8(22), 13-22   DOI
16 Freisleben H. P., Pederson J., 1977, Maturity Computer for Controlled Curing and Hardening of Concrete Strength, Nordisk Betong, 19-34